CN116313543A

CN116313543A - Energy storage device for high temperature applications

Info

Publication number: CN116313543A
Application number: CN202310187047.2A
Authority: CN
Inventors: 安德里亚·兰伯特; 马西莫·扎帕托; 斯特凡诺·卡门蒂; 马拉·塞拉佩德; 阿诺·尼古拉·吉格特
Original assignee: Eni SpA
Current assignee: Eni SpA
Priority date: 2018-04-17
Filing date: 2019-04-16
Publication date: 2023-06-23
Also published as: AU2019254466A1; BR112020021212A2; IT201800004596A1; EA202092496A1; MX2020010876A; CA3096567A1; EP3782176A1; CN112020756A; US20210375558A1; AU2019254466B2; US11923139B2; WO2019201887A1

Abstract

An energy storage device for high temperature applications, particularly supercapacitors, has a current collector element supporting a carbonaceous matrix modified or doped with a pseudocapacitive material comprising one or more transition metal dichalcogenides, transition metal oxides, and mixtures thereof, the carbonaceous matrix being in contact with a non-aqueous electrolyte composition, wherein inductive mechanisms may be utilized as an energy storage principle in addition to electric double layer mechanisms.

Description

Energy storage device for high temperature applications

The present application is a divisional application of patent application filed on 4/16 2019 with application number 201980026716.X and entitled "energy storage device for high temperature applications".

Technical Field

The present disclosure relates to an apparatus for use in a device requiring electrical energy, in particular the disclosed apparatus may be used as an energy storage apparatus for use in extreme environmental conditions. Electrolyte compositions that can be used in such devices are also disclosed.

Background

There is a clear need in many technical fields for compact energy storage. Since many devices are now required to be able to operate independently of the power grid, considerable effort has been made in the research of charge storage devices.

Devices such as "coin" or "button" sized batteries have limited energy values and have a relatively short useful life. Larger battery cells, so-called "accumulators", can be used which are able to output more electrical energy or to extend the service life, but can only be used without causing decomposition of the component materials (e.g. the liquid electrolyte required for the battery or accumulator function).

Another form of charge-storing device is a capacitor that holds an electrostatic charge that can be selectively rapidly discharged to accomplish limited work, for example, to activate a door lock or trigger an alarm system.

While both the battery and the capacitor have electrodes of opposite polarity to connect with external circuitry, they operate on different principles internally. The battery typically undergoes a chemical reaction between electrodes within the battery and the electrolyte, and as the chemical reaction proceeds, the battery releases electrical energy. When the chemical reaction is nearly complete, the battery will no longer be able to provide sufficient electrical energy and is considered to be depleted.

Instead, capacitors have internal non-conductor or dielectric material between spaced apart conductive plates, and can build up a high electrostatic charge on the dielectric material.

Thus, it can be said that state-of-the-art batteries tend to charge slowly, can hold charge for a limited shelf life, and can deliver predictable levels of electrical energy over a desired time frame, as compared to both types of devices. Instead, the capacitor can be repeatedly charged rapidly and a strong burst of energy can be delivered during the transient period at the discharge opportunity. Thus, these types of electrical energy storage devices tend to follow different development paths, but hybrid devices have been considered for some purposes.

It is an object of the presently disclosed subject matter to provide an electrical energy storage device that provides useful operating characteristics and advantageous characteristics over a wide range of operating conditions, including ambient and normal pressure, e.g., at room temperature.

It is another object of the presently disclosed subject matter to provide an electrical energy storage device that can be used in an apparatus or device that may be exposed to extreme temperature and pressure conditions such as those encountered in an underground environment.

It is another object of the presently disclosed subject matter to provide an electrolyte composition that can be used in an electrical energy storage device.

It has been recognized in the art that typical electrochemical energy storage devices are limited by thermally induced degradation of the electrolyte and separator when exposed to temperatures in excess of 100 ℃. Several commercially available devices contain liquid electrolytes (typically organic solvents with low boiling points). Thus, the maximum commercially acceptable temperature for such equipment is currently set at 85 ℃. Currently, the temperature range between 50 ℃ and 100 ℃ is considered in the art as "high temperature" exposure.

It is desirable to have an electrochemical energy storage device that can also operate over current "high temperature" profiles, such as, for example, desirably even up to 200 ℃ or higher.

The present disclosure relates to the development of capacitor-type devices, commonly referred to in the art as "supercapacitors" or "ultracapacitors". Supercapacitors are known per se. Supercapacitors differ from basic capacitors in that the capacitor has conductive metal plates separated by an insulator, and supercapacitors also have the conductive metal plates modified and the plates immersed in an electrolyte to act as electrodes. Further, a charge double layer is formed in the boundary between the electrode and the electrolyte. Each conductive metal plate in a supercapacitor is coated with a porous material having a larger surface area than the plate itself, such as activated carbon, which increases the amount of charge (capacitance) that can be stored in the supercapacitor at a given applied voltage.

The following documents may provide information useful in understanding the background of the present disclosure:

(1)US 8,760,851 B2；(2)US 2012/0156528 A1；(3)US 2013/0342962 A1；

(4)WO 2013/067540 A1；(5)US 2014/057164 A1；(6)CN 2013/10570159；

(7)CN 2015/10821905。

disclosure of Invention

In the present disclosure, an energy storage device is described, particularly for high temperature applications, comprising a current collector element supporting a carbonaceous matrix modified or doped with pseudocapacitive materials, which carbonaceous matrix is in contact with a non-aqueous electrolyte composition, wherein it is proposed that inductive mechanisms may be utilized as an energy storage principle in addition to electric double layer mechanisms. The carbonaceous matrix may be formed from one or more transition metals (M) selected from chalcogenides, oxides and mixtures thereof ^t ) Compound modification or doping. The apparatus may include a transition metal dichalcogenide, and optionally also a transition metal oxide. The use of modified or doped carbonaceous matrices as active materials enables the critical functional requirements of the intended use to be met. The active material may include the materials described below.

Transition metal (M) ^t ) May be selected from groups 3 to 12 of the periodic table of elements, and in some embodiments, for example, can be selected from aluminum (Al), titanium (Ti), vanadium (V), chromium (Cr), manganese (Mn), iron (Fe), cobalt (Co), nickel (Ni), copper (Cu),One or more transition metals of zinc (Zn), molybdenum (Mo), palladium (Pa), silver (Ag), cadmium (Cd), tungsten (W), preferably based on the oxide [ M ] ^t O _x ](where x corresponds to the available valence of the metal M) or chalcogenide forms [ M ^t X ^c ₂ ]The semiconductor properties exhibited at that time are selected.

Chalcogen (X) ^c ) For example, sulfur (S), selenium (Se) or tellurium (Te), wherein sulfur is conveniently available in the greatest abundance.

Dichalcogenides [ M ] ^t X ^c ₂ ]For example, moS, alone or in various combinations thereof ₂ 、MoSe ₂ 、WS ₂ 、WSe ₂ 、TeS ₂ 、TeSe ₂ . The following are currently possible component materials for this purpose: tiS alone or in various combinations ₂ 、TaS ₂ 、ZrS ₂ 、Bi ₂ S ₃ 、Bi ₂ Se ₃ 、Bi ₂ Te ₃ 、MoSe ₂ 、TaSe ₂ 、NbSe ₂ 、MoTe ₂ 、NiTe ₂ 、BiTe ₂ 、GeS ₂ 、GeSe ₂ 、GeTe、ZnS、ZnSe、EuSe、Ag ₂ S、Ag ₂ Se、Ag ₂ Te、FeS ₂ 、Fe ₇ S ₈ 、Fe ₃ S4、FeSe ₂ 、Fe ₃ Se4、β-FeSe _x 、In ₂ S ₃ 、SnS、SnS ₂ 、SnSe、SnTe、CuS、Cu ₂ S、Cu ₂ -xSe、Sb ₂ S ₃ 、Sb ₂ Te ₃ 、MnS、MnSe、CoS ₂ 、CoS ₃ 、CoTe、NiS、NiSe、NiTe、VS ₂ 。

The current collector element may comprise a metal component, optionally supported on other materials such as plastic, glass or ceramic, and may be connected to the other components by an electrical conductor element to form part of an electrical circuit for charging or discharging purposes, wherein the electrical circuit may comprise: a power source or a generator. The current collector element may be referred to as a composite positive electrode and a composite negative electrode. The metal component may be constructed in a variety of physical forms, optionally in a flexible form, such as a mesh, foil, foam, sponge, sheet, scroll, plate, coil, rod, etc., to which the modified or doped carbonaceous matrix composition has been applied, for example as a conductive adhesive layer or continuous coating.

The current collector may be prepared by a treatment such as surface modification (e.g., to increase surface roughness) or by using dendritic copper foil electrodeposited on a current collector substrate to enhance the coating or loading of the active material. The current collector thus prepared more readily receives a slurry of the coating and demonstrates improved adhesion of the intended coating.

Carbon coated metal current collectors may exhibit improved performance in the device because interactions between the electrolyte and the current collector surface may be reduced without adversely affecting the conductance across the interface.

In constructing the device, improved performance may be achieved by employing an asymmetric structure, for example, wherein the first electrode is formed using an electric double layer material (EDL) and the second electrode comprises a pseudocapacitive material (PC), for example as an EDL/PC mixture. Such an asymmetric device assembled from two different electrode materials can provide a wide operating voltage window, thereby increasing energy density.

The carbonaceous matrix may be based on graphene, which is a very low density/high surface area form of carbon. A carbonaceous matrix may be provided for the disclosed use as a graphene aerogel or similar low density carbon-based matrix that exhibits a large surface area and serves as a scaffold to support pseudocapacitive materials. Various forms of high surface area carbon are commercially available and include activated carbon, carbon fibers, or any of graphite, carbon nanotubes, carbon aerogel or carbon fiber fabrics or cloths or belts, such as rayon or viscose. The carbonaceous matrix may be porous, microporous or nanoporous, whereby ionic liquids or electrolytes may be adsorbed or infiltrated into the carbonaceous matrix.

Graphene oxide which can be dispersed in water and subjected to a hydrothermal reaction (graphene oxide) can be obtained by following the so-called "Hummers method" (William s. Hummers jr., richard E.Offeman, J.Am.Chem.Soc.,1958, 80 (6), pages 1339 to 1339, DOI:10.1021/ja01539a017, publication date: 3 month 1958) so as to obtain a reduced form which rearranges graphene in 3D form into a high surface area form after freeze-drying.

An alternative method of obtaining graphene oxide may be one of the methods known in the art as the "Brodie method", "staudenmailer method", "Hofmann method" and "Tour method".

In order to introduce the desired modification or doping of the carbonaceous matrix by the pseudocapacitive material, the graphene matrix obtained by the Hummers method, prior to hydrothermal treatment, a precursor for the intended transition metal chalcogenide/transition metal oxide may be introduced into the graphene oxide or graphene oxide dispersion in water. For example, phosphomolybdic acid and L-cysteine can be used for MoS ₂ Co-synthesis of nanoplatelets.

In alternative embodiments, pseudocapacitive materials may be introduced into the carbonaceous substrate by other wet or dry techniques such as, for example, electrodeposition, chemical vapor deposition, sputtering, atomic layer deposition, and the like.

The devices disclosed herein may include an electrolyte in a liquid medium selected from the group consisting of high boiling temperature solvents and ionic liquids, the electrolyte including one or more salts selected from the group consisting of organic salts and inorganic salts. The devices disclosed herein use in particular non-aqueous electrolyte compositions, and preferred embodiments of the devices are designed to exclude, to the extent possible, the ingress of harmful moisture or harmful moisture.

Embodiments may employ electrolyte compositions in liquid, polymer or gel form.

The polymer gel type will include a polymer matrix; optionally a plasticizer or viscosity modifier or an aprotic solvent; and an ionic salt as an electrolyte. This results in a suitable coating composition for plating or covering the current collector or electrode.

Various polymers have been proposed for gel electrolyte applications, including polyacrylonitrile "PAN", polyoxyethylene "PEO", polymethyl methacrylate "PMMA", polyvinylidene fluoride "PVDF" and poly (vinylidene fluoride-co-hexafluoropropylene) (PVDF-HFP).

Solvents and co-solvents that may be used as liquid carriers for polymer preparation may include, for example, acetone, tetrahydrofuran "THF", dimethylacetamide "DMAc", dimethylformamide "DMF", N-methyl-2-pyrrolidone "NMP" and other aprotic organic solvents.

In embodiments, for example, a gel polymer electrolyte may be obtained by mixing a polymer solution such as poly (vinylidene fluoride-hexafluoropropylene) "PVDF-HFP" (dissolved in a solvent) with an ionic liquid, as described in [ Lu, wen, et al, "Incorporating ionic liquid electrolytes into polymer gels for solid-state ultra capacitors ]" Journal of the Electrochemical Society 155.5.5 (2008): A361-A367 ]. In this way, the use of a spacer can be avoided, increasing the mechanical stability of the device. The polymer electrolyte can be used as both an ion conductor and a separator to avoid shorting when the electrodes are bent, thereby greatly simplifying the fabrication process of the device.

The electrolyte, optionally implemented as a gel-like material, may comprise a dielectric particulate material, optionally a ceramic or ceramic composite material, for example nanoparticles of an inorganic material such as alumina, titania, magnesium silicate, etc., or for example a clay such as any of bentonite, montmorillonite, kaolinite, terra alba, laponite clay (laponite clay), conveniently bentonite, or a combination of any of these dielectric particulate materials.

Electrolytes useful in the present devices include nonaqueous solvents, cations and anions, which may be organic or inorganic salts, optionally mixed with an ionic liquid.

The following table shows solvents that are considered candidates for use in the electrolyte compositions of the devices disclosed herein, especially for high temperature applications, because these solvents do not undergo a change to the gaseous state at normal (sea level) atmospheric pressure until a temperature of at least 150 ℃ is reached.

These solvents may be used as diluents for the electrolyte compositions disclosed herein.

The cation may be obtained by including at least one quaternary ammonium salt in the non-aqueous electrolyte composition. Suitable cations can be selected without limitation from the following list (i):

(i) Tetrabutylammonium, 1-ethyl 3-methylimidazolium, 1-butyl-3-methylimidazolium, 1- (3-cyanopropyl) -3-methylimidazolium, 1, 2-dimethyl-3-propylimidazolium, 1, 3-bis (3-cyanopropyl) imidazolium, 1, 3-diethoxyimidazolium, 1-butyl-1-methylpiperidinium, 1-butyl-2, 3-dimethylimidazolium, 1-butyl-4-methylpyridinium, 1-butylpyridinium, 1-decyl-3-methylimidazolium, 3-methyl-1-propylpyridinium, singly or in combination of two or more thereof.

The anions can be obtained by including at least one salt in the nonaqueous electrolyte composition. Suitable anions can be selected without limitation from the following list (ii):

(ii) Ethyl sulfate, methyl sulfate, thiocyanate, acetate, chloride, mesylate, tetrachloroaluminate, tetrafluoroborate, hexafluorophosphate, triflate, bis (pentafluoroethanesulfonate) imide, trifluoro (trifluoromethyl) borate, bis (trifluoromethanesulfonate) imide, tris (trifluoromethane 3-sulfonate) methide, or referred to as tris (trifluoromethanesulfonyl) methane, dicyandiamide, alone or in combination of two or more thereof.

The proposed electrolyte composition based on a non-aqueous material comprising inorganic salts in an organic electrolyte is novel and is used with an electrode formed of a transition metal dichalcogenide modified or doped carbonaceous matrix composite material to form an electrical device with high innovativeness, especially for high temperature applications of capacitive electrical energy storage devices.

In an embodiment, an electrical energy storage device, particularly a "supercapacitor," includes a metal current collector having at least one surface covered with a carbonaceous matrix modified or doped with a pseudocapacitive material, such as a transition metal dichalcogenide nano-meterStructures, e.g. based on MoS ₂ 。

In one method, the carbonaceous matrix is based on graphene, which can be obtained by treating graphite powder that can be oxidized, expanded and exfoliated according to the so-called Hummer method or any equivalent method described above for obtaining graphene oxide. The resulting Graphene Oxide (GO) powder can be easily dispersed in water, and the solution can be used for hydrothermal reactions in order to obtain both reduction of GO (reduced graphene oxide-rGO) and 3D alignment with high surface area (after freeze drying) -so-called "aerogel".

To be composed of metal sulfide (MS _x ) Or metal oxide (MO _x ) Modified or doped 3D rGO aerogel, where x corresponds to the available valence of metal M, it is sufficient to simply add a suitable precursor to GO dispersion prior to hydrothermal synthesis (e.g. co-synthesizing MoS using phosphomolybdic acid and L-cysteine ₂ Nanoplatelets).

The resulting material may be mixed with a binder (typically a polymer such as PVDF, PTFE, polythiophene, poly (2, 3-dihydrothieno-1, 4-dioxin) -Poly (styrene sulfonate) (Poly (2, 3-dihydrothiaeno-1, 4-dioxan) -Poly (styrenesulfonate)) (i.e., PEDOT: PSS) or any other polymer capable of withstanding temperatures up to 200 ℃ without deleterious degradation) dissolved in a suitable solvent to obtain a slurry, paste having a viscosity suitable for deposition onto a current collector (which may be metal or carbon-based) in the shape of, for example, a wire, foil, mesh, foam or sponge by screen printing or drop coating (drop-casting).

Alternative binders for slurry production may be water-based processing binders such as styrene butadiene copolymer (SBR), xanthan gum, polyacrylic acid (PAA) and binders modified with Na-modified binders (NaPAA), sodium alginate, polyamideimide (PAI), fluoroacrylic latex binders and cellulose-based binders (carboxymethyl cellulose (CMC) and binders modified with lithium salt (Li-CMC), sodium salt (Na-CMC), polyurethane (PU/CMC), polyacrylic acid (PAA/CMC), poly (sodium acrylate) (NaPAA-g-CMC copolymer), microfibrillated cellulose (MFC) and modified with polypyrrole (MFC/PPy).

If a planar configuration is chosen, slurry can be deposited on both sides of the current collector to increase the available surface area and thus the capacitance of the device.

Polyimide tape (or any other polymer capable of withstanding temperatures up to 200 ℃ without deleterious degradation-also contemplated as a material for the separator) may be used as an adhesive layer to which a current collector may be attached to facilitate the subsequent device structure forming process.

After the solvothermal evaporation, the electrodes may be assembled in a parallel configuration with a separator sandwiched between the electrodes. The separator may be a porous polymer (e.g., PTFE, PVDF, polyimide, etc.) with suitable thermal stability properties, or made of glass wool or fibers or ceramics.

The current collector may be cut into a rectangular shape with protrusions on the current collector for use as electrical contacts, or may be cut into any other shape.

The resulting multilayer may be rolled into a cylindrical shape in a rolled (vortex) form or held in a planar configuration and secured with additional polyimide tape. The vortex device may allow the separator to permeate and empty of air by immersing it in an electrolyte solution to fill the electrolyte and subjecting it to a vacuum process such that the entire system is maintained in a low pressure (vacuum) environment. Alternatively, the layers may be assembled into a "coin" cell, a "coffee pack" (pouch) cell, or any other structure.

After filling the electrolyte, the device may be coated with a layer of a photocurable resin (preferably an ultraviolet curable resin) and irradiated with ultraviolet rays to completely polymerize the resin, thereby sealing the device. This step may be repeated several times to improve the seal and obtain a continuous and uniform polymer film.

In assembling the device, appropriate considerations should be given to select minor components of the selected construction of the device for high temperature applications (e.g., O-rings or seals), avoid the use of, for example, standard polypropylene materials, and replace one of the high temperature operating characteristics such as a customized O-ring of Polytetrafluoroethylene (PTFE) or perfluoroalkoxy copolymer (PFA) or Ethylene Tetrafluoroethylene (ETFE) or Fluorinated Ethylene Propylene (FEP), or the encapsulation of an O-ring using such fluorocarbon polymers, orUsing flexible high temperature working range graphite materials (e.g

) Is provided.

Drawings

For exemplary further explanation of the present disclosure, reference will be made hereinafter to the accompanying drawings, which include:

FIG. 1 shows a method for inclusion of doped MoS ₂ A graphical representation of cyclic voltammetry recorded between 30 ℃ and 200 ℃ at a scan rate of 30mV/s for a device of reduced graphene oxide material;

FIG. 2 shows a graphical representation of thermal analysis (TGA and DSC) to evaluate the disclosed doping with MoS ₂ Optimal thermal stability of graphene oxide up to 220 ℃; and

fig. 3 schematically shows the assembly of the supercapacitor device.

Detailed Description

Referring to FIG. 1, at Shen, baoshou, et al Journal of Materials Chemistry A4.21.21 (2016): comparison of the materials discussed in 8316-8327 and Borges, raquel s, et al Scientific reports (2013) with embodiments according to the present disclosure reveals that the embodiments disclosed herein exhibit up to 210F/g (corresponding to 365 mF/cm) at 200 deg.c ² ) Is equal to 2.1V. These values are excellent in specific capacitance (weight and area density). Specific capacitance values recorded at different temperatures are collected in table 1 below.

TABLE 1 capacitance values recorded at different temperatures

Temperature (. Degree. C.)	C _s (F/G)	C _s (mF/cm ² )
			30	174,9	306,2
50	202,1	353,7
			100	209,2	366,1
150	190,8	333,9
			200	208,5	364,6

The apparatus, which represents one possible embodiment of one possible assembly method without limitation, can be assembled according to the following illustrative procedure, with reference to fig. 3, wherein in a first stage the metal current collector element 1 is formed into the desired shape by cutting or punching from a metal plate, optionally with protruding conductive connectors 2. An active material, in the form of a slurry, gel or paste as described above and comprising a carbonaceous matrix modified or doped with a pseudocapacitive material and a polymeric binder, may be applied to the current collector element 1 in a controlled manner (e.g., using a doctor blade) to form a deposit 3 on at least one surface of the current collector element 1 covering a selected surface area to provide the first electrode 4. The electrodes may be mounted on a flexible support substrate 5. The same procedure may be repeated to provide the second electrode 8. The electrodes 4, 8 may be heat treated under reduced pressure to substantially remove solvent and minimize the presence of moisture prior to any subsequent assembly steps. The electrodes 3, 8 are oriented and juxtaposed in facing spaced relation and a porous polymeric sheet separator 6 of suitable thermal stability is introduced between the electrodes 4, 8 to form a layered assembly. Optionally, the layered assembly may be swirled into the generally cylindrical body 9. The vortex cylindrical body 9 may be introduced into the electrolyte solution, for example by immersion in an electrolyte bath, and subjected to reduced pressure to facilitate permeation of the separator 6 by the electrolyte solution and evacuation of air. After filling the electrolyte, a layer of photocurable resin may be coated on the cylindrical body 9 and subjected to Ultraviolet (UV) irradiation to polymerize the resin sufficiently, thereby providing a sealing device. The resin coating step may be repeated, and other coating steps may optionally be performed, to provide a sealing device having a continuous and uniform polymer film surface.

Advantages of the disclosed methods, materials, and apparatus include the ability to enable apparatus that can operate at the operating temperatures required for subsurface (e.g., downhole) applications (up to 200 ℃ or higher) utilizing lower viscosity and higher ion mobility electrolytes in combination with composite electrodes (e.g., 3D graphene networks containing pseudocapacitive materials) capable of delivering capacitance values (higher than those obtainable with carbon allotropes alone) relative to known products.

Claims

1. An energy storage device comprising current collector elements, each of the current collector elements comprising at least one surface covered with an active material having a graphene matrix and a polymeric binder, the polymeric binder being non-aqueous processing based binder and capable of withstanding temperatures up to 200 ℃ without degradation, the graphene matrix being modified or doped with a transition metal dichalcogenide comprising one or more transition metal compounds, the device being filled with a non-aqueous electrolyte composition such that the graphene matrix is in contact with the non-aqueous electrolyte composition comprising cations and anions in a liquid medium selected from high boiling temperature solvents and ionic liquids, the high boiling temperature solvents selected to undergo a change in the gaseous state at normal atmospheric pressure and temperatures of at least 150 ℃.

2. The apparatus of claim 1, wherein the non-aqueous electrolyte composition comprises one or more salts selected from the group consisting of organic salts and inorganic salts.

3. The apparatus of any one of the preceding claims, wherein the non-aqueous electrolyte composition comprises at least one quaternary ammonium salt.

4. The device of any one of the preceding claims, wherein the non-aqueous electrolyte composition comprises at least one cation selected from tetrabutylammonium, 1-ethyl 3-methylimidazolium, 1-butyl-3-methylimidazolium, 1- (3-cyanopropyl) -3-methylimidazolium, 1, 2-dimethyl-3-propylimidazolium, 1, 3-bis (3-cyanopropyl) imidazolium, 1, 3-diethoxyimidazolium, 1-butyl-1-methylpiperidinium, 1-butyl-2, 3-dimethylimidazolium, 1-butyl-4-methylpyridinium, 1-butylpyridinium, 1-decyl-3-methylimidazolium, 3-methyl-1-propylpyridinium.

5. The apparatus of any one of the preceding claims, wherein the non-aqueous electrolyte composition comprises at least one anion selected from the group consisting of ethylsulfate, methylsulfate, thiocyanate, acetate, chloride, methanesulfonate, tetrachloroaluminate, tetrafluoroborate, hexafluorophosphate, trifluoromethanesulfonate, bis (pentafluoroethanesulfonate) imide, trifluoro (trifluoromethyl) borate, bis (trifluoromethanesulfonate) imide, tris (trifluoromethane3 sulfonate) methide, dicyandiamide.

6. The apparatus of any one of the preceding claims, wherein the non-aqueous electrolyte composition comprises at least one of: glycerol, ethylene glycol, diethylene glycol dimethyl ether (diglyme), propylene carbonate, hexamethylphosphoramide (HMPA), N-methyl-2-pyrrolidone (NMP), dimethyl sulfoxide (DMSO), dimethylformamide (DMF), hexamethylphosphoramide (HMPT).

7. The apparatus of any one of the preceding claims, wherein the graphene matrix is modified or doped by a method selected from electrodeposition, chemical Vapor Deposition (CVD), sputtering, atomic layer deposition.

8. The apparatus of any one of the preceding claims, wherein the graphene matrix is modified or doped with the at least one transition metal dichalcogenide and at least one transition metal oxide.

9. The apparatus of claim 8, wherein the graphene matrix is modified or doped with a transition metal dichalcogenide comprising one or more of: moS (MoS) ₂ 、MoSe ₂ 、WS ₂ 、WSe ₂ 、TeS ₂ 、TeSe ₂ 、TiS ₂ 、TaS ₂ 、ZrS ₂ 、MoSe ₂ 、TaSe ₂ 、NbSe ₂ 、MoTe ₂ 、NiTe ₂ 、BiTe ₂ 、GeS ₂ 、GeSe ₂ 、GeTeZn ₂ 、FeS ₂ 、FeSe ₂ 、SnS ₂ 、CoS ₂ 、VS ₂ Alone or in various combinations.

10. The apparatus of any one of the preceding claims, wherein the current collector element comprises a metal component, optionally supported on a plastic or ceramic, and configured as one of a mesh, foil, foam, sponge, sheet, scroll, plate, coil, or rod.

11. The apparatus of any one of the preceding claims, wherein the graphene matrix comprises graphene aerogel and the transition metal dichalcogenide comprises molybdenum disulfide.

12. The device of any one of the preceding claims, configured as a supercapacitor and comprising a plurality of current collector elements acting as positive and negative electrodes, having electrical conductor elements for connecting the current collector elements to an external circuit, the plurality of current collector elements being respectively in contact with a non-aqueous electrolyte composition confined within the device and having separators located between the current collector elements such that the positive and negative electrodes are separated.

13. The apparatus of claim 12, wherein the separator comprises a thermally stable polymer or ceramic or glass and is porous.

14. The device according to claim 12 or 13, wherein the device is constructed in a multi-layer structure, filled with electrolyte and sealed with polymer or resin, capable of being assembled into a "coin" cell or a "coffee bag" (pouch) cell.

15. The apparatus of claim 14, wherein the apparatus is sealed using a photocurable resin.